Issue #6644: Fix compile error on AIX.
[python.git] / Lib / difflib.py
blob679bd2a01a1981f43cce91a9a1385fe3f70183e8
1 #! /usr/bin/env python
3 """
4 Module difflib -- helpers for computing deltas between objects.
6 Function get_close_matches(word, possibilities, n=3, cutoff=0.6):
7 Use SequenceMatcher to return list of the best "good enough" matches.
9 Function context_diff(a, b):
10 For two lists of strings, return a delta in context diff format.
12 Function ndiff(a, b):
13 Return a delta: the difference between `a` and `b` (lists of strings).
15 Function restore(delta, which):
16 Return one of the two sequences that generated an ndiff delta.
18 Function unified_diff(a, b):
19 For two lists of strings, return a delta in unified diff format.
21 Class SequenceMatcher:
22 A flexible class for comparing pairs of sequences of any type.
24 Class Differ:
25 For producing human-readable deltas from sequences of lines of text.
27 Class HtmlDiff:
28 For producing HTML side by side comparison with change highlights.
29 """
31 __all__ = ['get_close_matches', 'ndiff', 'restore', 'SequenceMatcher',
32 'Differ','IS_CHARACTER_JUNK', 'IS_LINE_JUNK', 'context_diff',
33 'unified_diff', 'HtmlDiff', 'Match']
35 import heapq
36 from collections import namedtuple as _namedtuple
37 from functools import reduce
39 Match = _namedtuple('Match', 'a b size')
41 def _calculate_ratio(matches, length):
42 if length:
43 return 2.0 * matches / length
44 return 1.0
46 class SequenceMatcher:
48 """
49 SequenceMatcher is a flexible class for comparing pairs of sequences of
50 any type, so long as the sequence elements are hashable. The basic
51 algorithm predates, and is a little fancier than, an algorithm
52 published in the late 1980's by Ratcliff and Obershelp under the
53 hyperbolic name "gestalt pattern matching". The basic idea is to find
54 the longest contiguous matching subsequence that contains no "junk"
55 elements (R-O doesn't address junk). The same idea is then applied
56 recursively to the pieces of the sequences to the left and to the right
57 of the matching subsequence. This does not yield minimal edit
58 sequences, but does tend to yield matches that "look right" to people.
60 SequenceMatcher tries to compute a "human-friendly diff" between two
61 sequences. Unlike e.g. UNIX(tm) diff, the fundamental notion is the
62 longest *contiguous* & junk-free matching subsequence. That's what
63 catches peoples' eyes. The Windows(tm) windiff has another interesting
64 notion, pairing up elements that appear uniquely in each sequence.
65 That, and the method here, appear to yield more intuitive difference
66 reports than does diff. This method appears to be the least vulnerable
67 to synching up on blocks of "junk lines", though (like blank lines in
68 ordinary text files, or maybe "<P>" lines in HTML files). That may be
69 because this is the only method of the 3 that has a *concept* of
70 "junk" <wink>.
72 Example, comparing two strings, and considering blanks to be "junk":
74 >>> s = SequenceMatcher(lambda x: x == " ",
75 ... "private Thread currentThread;",
76 ... "private volatile Thread currentThread;")
77 >>>
79 .ratio() returns a float in [0, 1], measuring the "similarity" of the
80 sequences. As a rule of thumb, a .ratio() value over 0.6 means the
81 sequences are close matches:
83 >>> print round(s.ratio(), 3)
84 0.866
85 >>>
87 If you're only interested in where the sequences match,
88 .get_matching_blocks() is handy:
90 >>> for block in s.get_matching_blocks():
91 ... print "a[%d] and b[%d] match for %d elements" % block
92 a[0] and b[0] match for 8 elements
93 a[8] and b[17] match for 21 elements
94 a[29] and b[38] match for 0 elements
96 Note that the last tuple returned by .get_matching_blocks() is always a
97 dummy, (len(a), len(b), 0), and this is the only case in which the last
98 tuple element (number of elements matched) is 0.
100 If you want to know how to change the first sequence into the second,
101 use .get_opcodes():
103 >>> for opcode in s.get_opcodes():
104 ... print "%6s a[%d:%d] b[%d:%d]" % opcode
105 equal a[0:8] b[0:8]
106 insert a[8:8] b[8:17]
107 equal a[8:29] b[17:38]
109 See the Differ class for a fancy human-friendly file differencer, which
110 uses SequenceMatcher both to compare sequences of lines, and to compare
111 sequences of characters within similar (near-matching) lines.
113 See also function get_close_matches() in this module, which shows how
114 simple code building on SequenceMatcher can be used to do useful work.
116 Timing: Basic R-O is cubic time worst case and quadratic time expected
117 case. SequenceMatcher is quadratic time for the worst case and has
118 expected-case behavior dependent in a complicated way on how many
119 elements the sequences have in common; best case time is linear.
121 Methods:
123 __init__(isjunk=None, a='', b='')
124 Construct a SequenceMatcher.
126 set_seqs(a, b)
127 Set the two sequences to be compared.
129 set_seq1(a)
130 Set the first sequence to be compared.
132 set_seq2(b)
133 Set the second sequence to be compared.
135 find_longest_match(alo, ahi, blo, bhi)
136 Find longest matching block in a[alo:ahi] and b[blo:bhi].
138 get_matching_blocks()
139 Return list of triples describing matching subsequences.
141 get_opcodes()
142 Return list of 5-tuples describing how to turn a into b.
144 ratio()
145 Return a measure of the sequences' similarity (float in [0,1]).
147 quick_ratio()
148 Return an upper bound on .ratio() relatively quickly.
150 real_quick_ratio()
151 Return an upper bound on ratio() very quickly.
154 def __init__(self, isjunk=None, a='', b=''):
155 """Construct a SequenceMatcher.
157 Optional arg isjunk is None (the default), or a one-argument
158 function that takes a sequence element and returns true iff the
159 element is junk. None is equivalent to passing "lambda x: 0", i.e.
160 no elements are considered to be junk. For example, pass
161 lambda x: x in " \\t"
162 if you're comparing lines as sequences of characters, and don't
163 want to synch up on blanks or hard tabs.
165 Optional arg a is the first of two sequences to be compared. By
166 default, an empty string. The elements of a must be hashable. See
167 also .set_seqs() and .set_seq1().
169 Optional arg b is the second of two sequences to be compared. By
170 default, an empty string. The elements of b must be hashable. See
171 also .set_seqs() and .set_seq2().
174 # Members:
176 # first sequence
178 # second sequence; differences are computed as "what do
179 # we need to do to 'a' to change it into 'b'?"
180 # b2j
181 # for x in b, b2j[x] is a list of the indices (into b)
182 # at which x appears; junk elements do not appear
183 # fullbcount
184 # for x in b, fullbcount[x] == the number of times x
185 # appears in b; only materialized if really needed (used
186 # only for computing quick_ratio())
187 # matching_blocks
188 # a list of (i, j, k) triples, where a[i:i+k] == b[j:j+k];
189 # ascending & non-overlapping in i and in j; terminated by
190 # a dummy (len(a), len(b), 0) sentinel
191 # opcodes
192 # a list of (tag, i1, i2, j1, j2) tuples, where tag is
193 # one of
194 # 'replace' a[i1:i2] should be replaced by b[j1:j2]
195 # 'delete' a[i1:i2] should be deleted
196 # 'insert' b[j1:j2] should be inserted
197 # 'equal' a[i1:i2] == b[j1:j2]
198 # isjunk
199 # a user-supplied function taking a sequence element and
200 # returning true iff the element is "junk" -- this has
201 # subtle but helpful effects on the algorithm, which I'll
202 # get around to writing up someday <0.9 wink>.
203 # DON'T USE! Only __chain_b uses this. Use isbjunk.
204 # isbjunk
205 # for x in b, isbjunk(x) == isjunk(x) but much faster;
206 # it's really the __contains__ method of a hidden dict.
207 # DOES NOT WORK for x in a!
208 # isbpopular
209 # for x in b, isbpopular(x) is true iff b is reasonably long
210 # (at least 200 elements) and x accounts for more than 1% of
211 # its elements. DOES NOT WORK for x in a!
213 self.isjunk = isjunk
214 self.a = self.b = None
215 self.set_seqs(a, b)
217 def set_seqs(self, a, b):
218 """Set the two sequences to be compared.
220 >>> s = SequenceMatcher()
221 >>> s.set_seqs("abcd", "bcde")
222 >>> s.ratio()
223 0.75
226 self.set_seq1(a)
227 self.set_seq2(b)
229 def set_seq1(self, a):
230 """Set the first sequence to be compared.
232 The second sequence to be compared is not changed.
234 >>> s = SequenceMatcher(None, "abcd", "bcde")
235 >>> s.ratio()
236 0.75
237 >>> s.set_seq1("bcde")
238 >>> s.ratio()
242 SequenceMatcher computes and caches detailed information about the
243 second sequence, so if you want to compare one sequence S against
244 many sequences, use .set_seq2(S) once and call .set_seq1(x)
245 repeatedly for each of the other sequences.
247 See also set_seqs() and set_seq2().
250 if a is self.a:
251 return
252 self.a = a
253 self.matching_blocks = self.opcodes = None
255 def set_seq2(self, b):
256 """Set the second sequence to be compared.
258 The first sequence to be compared is not changed.
260 >>> s = SequenceMatcher(None, "abcd", "bcde")
261 >>> s.ratio()
262 0.75
263 >>> s.set_seq2("abcd")
264 >>> s.ratio()
268 SequenceMatcher computes and caches detailed information about the
269 second sequence, so if you want to compare one sequence S against
270 many sequences, use .set_seq2(S) once and call .set_seq1(x)
271 repeatedly for each of the other sequences.
273 See also set_seqs() and set_seq1().
276 if b is self.b:
277 return
278 self.b = b
279 self.matching_blocks = self.opcodes = None
280 self.fullbcount = None
281 self.__chain_b()
283 # For each element x in b, set b2j[x] to a list of the indices in
284 # b where x appears; the indices are in increasing order; note that
285 # the number of times x appears in b is len(b2j[x]) ...
286 # when self.isjunk is defined, junk elements don't show up in this
287 # map at all, which stops the central find_longest_match method
288 # from starting any matching block at a junk element ...
289 # also creates the fast isbjunk function ...
290 # b2j also does not contain entries for "popular" elements, meaning
291 # elements that account for more than 1% of the total elements, and
292 # when the sequence is reasonably large (>= 200 elements); this can
293 # be viewed as an adaptive notion of semi-junk, and yields an enormous
294 # speedup when, e.g., comparing program files with hundreds of
295 # instances of "return NULL;" ...
296 # note that this is only called when b changes; so for cross-product
297 # kinds of matches, it's best to call set_seq2 once, then set_seq1
298 # repeatedly
300 def __chain_b(self):
301 # Because isjunk is a user-defined (not C) function, and we test
302 # for junk a LOT, it's important to minimize the number of calls.
303 # Before the tricks described here, __chain_b was by far the most
304 # time-consuming routine in the whole module! If anyone sees
305 # Jim Roskind, thank him again for profile.py -- I never would
306 # have guessed that.
307 # The first trick is to build b2j ignoring the possibility
308 # of junk. I.e., we don't call isjunk at all yet. Throwing
309 # out the junk later is much cheaper than building b2j "right"
310 # from the start.
311 b = self.b
312 n = len(b)
313 self.b2j = b2j = {}
314 populardict = {}
315 for i, elt in enumerate(b):
316 if elt in b2j:
317 indices = b2j[elt]
318 if n >= 200 and len(indices) * 100 > n:
319 populardict[elt] = 1
320 del indices[:]
321 else:
322 indices.append(i)
323 else:
324 b2j[elt] = [i]
326 # Purge leftover indices for popular elements.
327 for elt in populardict:
328 del b2j[elt]
330 # Now b2j.keys() contains elements uniquely, and especially when
331 # the sequence is a string, that's usually a good deal smaller
332 # than len(string). The difference is the number of isjunk calls
333 # saved.
334 isjunk = self.isjunk
335 junkdict = {}
336 if isjunk:
337 for d in populardict, b2j:
338 for elt in d.keys():
339 if isjunk(elt):
340 junkdict[elt] = 1
341 del d[elt]
343 # Now for x in b, isjunk(x) == x in junkdict, but the
344 # latter is much faster. Note too that while there may be a
345 # lot of junk in the sequence, the number of *unique* junk
346 # elements is probably small. So the memory burden of keeping
347 # this dict alive is likely trivial compared to the size of b2j.
348 self.isbjunk = junkdict.__contains__
349 self.isbpopular = populardict.__contains__
351 def find_longest_match(self, alo, ahi, blo, bhi):
352 """Find longest matching block in a[alo:ahi] and b[blo:bhi].
354 If isjunk is not defined:
356 Return (i,j,k) such that a[i:i+k] is equal to b[j:j+k], where
357 alo <= i <= i+k <= ahi
358 blo <= j <= j+k <= bhi
359 and for all (i',j',k') meeting those conditions,
360 k >= k'
361 i <= i'
362 and if i == i', j <= j'
364 In other words, of all maximal matching blocks, return one that
365 starts earliest in a, and of all those maximal matching blocks that
366 start earliest in a, return the one that starts earliest in b.
368 >>> s = SequenceMatcher(None, " abcd", "abcd abcd")
369 >>> s.find_longest_match(0, 5, 0, 9)
370 Match(a=0, b=4, size=5)
372 If isjunk is defined, first the longest matching block is
373 determined as above, but with the additional restriction that no
374 junk element appears in the block. Then that block is extended as
375 far as possible by matching (only) junk elements on both sides. So
376 the resulting block never matches on junk except as identical junk
377 happens to be adjacent to an "interesting" match.
379 Here's the same example as before, but considering blanks to be
380 junk. That prevents " abcd" from matching the " abcd" at the tail
381 end of the second sequence directly. Instead only the "abcd" can
382 match, and matches the leftmost "abcd" in the second sequence:
384 >>> s = SequenceMatcher(lambda x: x==" ", " abcd", "abcd abcd")
385 >>> s.find_longest_match(0, 5, 0, 9)
386 Match(a=1, b=0, size=4)
388 If no blocks match, return (alo, blo, 0).
390 >>> s = SequenceMatcher(None, "ab", "c")
391 >>> s.find_longest_match(0, 2, 0, 1)
392 Match(a=0, b=0, size=0)
395 # CAUTION: stripping common prefix or suffix would be incorrect.
396 # E.g.,
397 # ab
398 # acab
399 # Longest matching block is "ab", but if common prefix is
400 # stripped, it's "a" (tied with "b"). UNIX(tm) diff does so
401 # strip, so ends up claiming that ab is changed to acab by
402 # inserting "ca" in the middle. That's minimal but unintuitive:
403 # "it's obvious" that someone inserted "ac" at the front.
404 # Windiff ends up at the same place as diff, but by pairing up
405 # the unique 'b's and then matching the first two 'a's.
407 a, b, b2j, isbjunk = self.a, self.b, self.b2j, self.isbjunk
408 besti, bestj, bestsize = alo, blo, 0
409 # find longest junk-free match
410 # during an iteration of the loop, j2len[j] = length of longest
411 # junk-free match ending with a[i-1] and b[j]
412 j2len = {}
413 nothing = []
414 for i in xrange(alo, ahi):
415 # look at all instances of a[i] in b; note that because
416 # b2j has no junk keys, the loop is skipped if a[i] is junk
417 j2lenget = j2len.get
418 newj2len = {}
419 for j in b2j.get(a[i], nothing):
420 # a[i] matches b[j]
421 if j < blo:
422 continue
423 if j >= bhi:
424 break
425 k = newj2len[j] = j2lenget(j-1, 0) + 1
426 if k > bestsize:
427 besti, bestj, bestsize = i-k+1, j-k+1, k
428 j2len = newj2len
430 # Extend the best by non-junk elements on each end. In particular,
431 # "popular" non-junk elements aren't in b2j, which greatly speeds
432 # the inner loop above, but also means "the best" match so far
433 # doesn't contain any junk *or* popular non-junk elements.
434 while besti > alo and bestj > blo and \
435 not isbjunk(b[bestj-1]) and \
436 a[besti-1] == b[bestj-1]:
437 besti, bestj, bestsize = besti-1, bestj-1, bestsize+1
438 while besti+bestsize < ahi and bestj+bestsize < bhi and \
439 not isbjunk(b[bestj+bestsize]) and \
440 a[besti+bestsize] == b[bestj+bestsize]:
441 bestsize += 1
443 # Now that we have a wholly interesting match (albeit possibly
444 # empty!), we may as well suck up the matching junk on each
445 # side of it too. Can't think of a good reason not to, and it
446 # saves post-processing the (possibly considerable) expense of
447 # figuring out what to do with it. In the case of an empty
448 # interesting match, this is clearly the right thing to do,
449 # because no other kind of match is possible in the regions.
450 while besti > alo and bestj > blo and \
451 isbjunk(b[bestj-1]) and \
452 a[besti-1] == b[bestj-1]:
453 besti, bestj, bestsize = besti-1, bestj-1, bestsize+1
454 while besti+bestsize < ahi and bestj+bestsize < bhi and \
455 isbjunk(b[bestj+bestsize]) and \
456 a[besti+bestsize] == b[bestj+bestsize]:
457 bestsize = bestsize + 1
459 return Match(besti, bestj, bestsize)
461 def get_matching_blocks(self):
462 """Return list of triples describing matching subsequences.
464 Each triple is of the form (i, j, n), and means that
465 a[i:i+n] == b[j:j+n]. The triples are monotonically increasing in
466 i and in j. New in Python 2.5, it's also guaranteed that if
467 (i, j, n) and (i', j', n') are adjacent triples in the list, and
468 the second is not the last triple in the list, then i+n != i' or
469 j+n != j'. IOW, adjacent triples never describe adjacent equal
470 blocks.
472 The last triple is a dummy, (len(a), len(b), 0), and is the only
473 triple with n==0.
475 >>> s = SequenceMatcher(None, "abxcd", "abcd")
476 >>> s.get_matching_blocks()
477 [Match(a=0, b=0, size=2), Match(a=3, b=2, size=2), Match(a=5, b=4, size=0)]
480 if self.matching_blocks is not None:
481 return self.matching_blocks
482 la, lb = len(self.a), len(self.b)
484 # This is most naturally expressed as a recursive algorithm, but
485 # at least one user bumped into extreme use cases that exceeded
486 # the recursion limit on their box. So, now we maintain a list
487 # ('queue`) of blocks we still need to look at, and append partial
488 # results to `matching_blocks` in a loop; the matches are sorted
489 # at the end.
490 queue = [(0, la, 0, lb)]
491 matching_blocks = []
492 while queue:
493 alo, ahi, blo, bhi = queue.pop()
494 i, j, k = x = self.find_longest_match(alo, ahi, blo, bhi)
495 # a[alo:i] vs b[blo:j] unknown
496 # a[i:i+k] same as b[j:j+k]
497 # a[i+k:ahi] vs b[j+k:bhi] unknown
498 if k: # if k is 0, there was no matching block
499 matching_blocks.append(x)
500 if alo < i and blo < j:
501 queue.append((alo, i, blo, j))
502 if i+k < ahi and j+k < bhi:
503 queue.append((i+k, ahi, j+k, bhi))
504 matching_blocks.sort()
506 # It's possible that we have adjacent equal blocks in the
507 # matching_blocks list now. Starting with 2.5, this code was added
508 # to collapse them.
509 i1 = j1 = k1 = 0
510 non_adjacent = []
511 for i2, j2, k2 in matching_blocks:
512 # Is this block adjacent to i1, j1, k1?
513 if i1 + k1 == i2 and j1 + k1 == j2:
514 # Yes, so collapse them -- this just increases the length of
515 # the first block by the length of the second, and the first
516 # block so lengthened remains the block to compare against.
517 k1 += k2
518 else:
519 # Not adjacent. Remember the first block (k1==0 means it's
520 # the dummy we started with), and make the second block the
521 # new block to compare against.
522 if k1:
523 non_adjacent.append((i1, j1, k1))
524 i1, j1, k1 = i2, j2, k2
525 if k1:
526 non_adjacent.append((i1, j1, k1))
528 non_adjacent.append( (la, lb, 0) )
529 self.matching_blocks = non_adjacent
530 return map(Match._make, self.matching_blocks)
532 def get_opcodes(self):
533 """Return list of 5-tuples describing how to turn a into b.
535 Each tuple is of the form (tag, i1, i2, j1, j2). The first tuple
536 has i1 == j1 == 0, and remaining tuples have i1 == the i2 from the
537 tuple preceding it, and likewise for j1 == the previous j2.
539 The tags are strings, with these meanings:
541 'replace': a[i1:i2] should be replaced by b[j1:j2]
542 'delete': a[i1:i2] should be deleted.
543 Note that j1==j2 in this case.
544 'insert': b[j1:j2] should be inserted at a[i1:i1].
545 Note that i1==i2 in this case.
546 'equal': a[i1:i2] == b[j1:j2]
548 >>> a = "qabxcd"
549 >>> b = "abycdf"
550 >>> s = SequenceMatcher(None, a, b)
551 >>> for tag, i1, i2, j1, j2 in s.get_opcodes():
552 ... print ("%7s a[%d:%d] (%s) b[%d:%d] (%s)" %
553 ... (tag, i1, i2, a[i1:i2], j1, j2, b[j1:j2]))
554 delete a[0:1] (q) b[0:0] ()
555 equal a[1:3] (ab) b[0:2] (ab)
556 replace a[3:4] (x) b[2:3] (y)
557 equal a[4:6] (cd) b[3:5] (cd)
558 insert a[6:6] () b[5:6] (f)
561 if self.opcodes is not None:
562 return self.opcodes
563 i = j = 0
564 self.opcodes = answer = []
565 for ai, bj, size in self.get_matching_blocks():
566 # invariant: we've pumped out correct diffs to change
567 # a[:i] into b[:j], and the next matching block is
568 # a[ai:ai+size] == b[bj:bj+size]. So we need to pump
569 # out a diff to change a[i:ai] into b[j:bj], pump out
570 # the matching block, and move (i,j) beyond the match
571 tag = ''
572 if i < ai and j < bj:
573 tag = 'replace'
574 elif i < ai:
575 tag = 'delete'
576 elif j < bj:
577 tag = 'insert'
578 if tag:
579 answer.append( (tag, i, ai, j, bj) )
580 i, j = ai+size, bj+size
581 # the list of matching blocks is terminated by a
582 # sentinel with size 0
583 if size:
584 answer.append( ('equal', ai, i, bj, j) )
585 return answer
587 def get_grouped_opcodes(self, n=3):
588 """ Isolate change clusters by eliminating ranges with no changes.
590 Return a generator of groups with upto n lines of context.
591 Each group is in the same format as returned by get_opcodes().
593 >>> from pprint import pprint
594 >>> a = map(str, range(1,40))
595 >>> b = a[:]
596 >>> b[8:8] = ['i'] # Make an insertion
597 >>> b[20] += 'x' # Make a replacement
598 >>> b[23:28] = [] # Make a deletion
599 >>> b[30] += 'y' # Make another replacement
600 >>> pprint(list(SequenceMatcher(None,a,b).get_grouped_opcodes()))
601 [[('equal', 5, 8, 5, 8), ('insert', 8, 8, 8, 9), ('equal', 8, 11, 9, 12)],
602 [('equal', 16, 19, 17, 20),
603 ('replace', 19, 20, 20, 21),
604 ('equal', 20, 22, 21, 23),
605 ('delete', 22, 27, 23, 23),
606 ('equal', 27, 30, 23, 26)],
607 [('equal', 31, 34, 27, 30),
608 ('replace', 34, 35, 30, 31),
609 ('equal', 35, 38, 31, 34)]]
612 codes = self.get_opcodes()
613 if not codes:
614 codes = [("equal", 0, 1, 0, 1)]
615 # Fixup leading and trailing groups if they show no changes.
616 if codes[0][0] == 'equal':
617 tag, i1, i2, j1, j2 = codes[0]
618 codes[0] = tag, max(i1, i2-n), i2, max(j1, j2-n), j2
619 if codes[-1][0] == 'equal':
620 tag, i1, i2, j1, j2 = codes[-1]
621 codes[-1] = tag, i1, min(i2, i1+n), j1, min(j2, j1+n)
623 nn = n + n
624 group = []
625 for tag, i1, i2, j1, j2 in codes:
626 # End the current group and start a new one whenever
627 # there is a large range with no changes.
628 if tag == 'equal' and i2-i1 > nn:
629 group.append((tag, i1, min(i2, i1+n), j1, min(j2, j1+n)))
630 yield group
631 group = []
632 i1, j1 = max(i1, i2-n), max(j1, j2-n)
633 group.append((tag, i1, i2, j1 ,j2))
634 if group and not (len(group)==1 and group[0][0] == 'equal'):
635 yield group
637 def ratio(self):
638 """Return a measure of the sequences' similarity (float in [0,1]).
640 Where T is the total number of elements in both sequences, and
641 M is the number of matches, this is 2.0*M / T.
642 Note that this is 1 if the sequences are identical, and 0 if
643 they have nothing in common.
645 .ratio() is expensive to compute if you haven't already computed
646 .get_matching_blocks() or .get_opcodes(), in which case you may
647 want to try .quick_ratio() or .real_quick_ratio() first to get an
648 upper bound.
650 >>> s = SequenceMatcher(None, "abcd", "bcde")
651 >>> s.ratio()
652 0.75
653 >>> s.quick_ratio()
654 0.75
655 >>> s.real_quick_ratio()
659 matches = reduce(lambda sum, triple: sum + triple[-1],
660 self.get_matching_blocks(), 0)
661 return _calculate_ratio(matches, len(self.a) + len(self.b))
663 def quick_ratio(self):
664 """Return an upper bound on ratio() relatively quickly.
666 This isn't defined beyond that it is an upper bound on .ratio(), and
667 is faster to compute.
670 # viewing a and b as multisets, set matches to the cardinality
671 # of their intersection; this counts the number of matches
672 # without regard to order, so is clearly an upper bound
673 if self.fullbcount is None:
674 self.fullbcount = fullbcount = {}
675 for elt in self.b:
676 fullbcount[elt] = fullbcount.get(elt, 0) + 1
677 fullbcount = self.fullbcount
678 # avail[x] is the number of times x appears in 'b' less the
679 # number of times we've seen it in 'a' so far ... kinda
680 avail = {}
681 availhas, matches = avail.__contains__, 0
682 for elt in self.a:
683 if availhas(elt):
684 numb = avail[elt]
685 else:
686 numb = fullbcount.get(elt, 0)
687 avail[elt] = numb - 1
688 if numb > 0:
689 matches = matches + 1
690 return _calculate_ratio(matches, len(self.a) + len(self.b))
692 def real_quick_ratio(self):
693 """Return an upper bound on ratio() very quickly.
695 This isn't defined beyond that it is an upper bound on .ratio(), and
696 is faster to compute than either .ratio() or .quick_ratio().
699 la, lb = len(self.a), len(self.b)
700 # can't have more matches than the number of elements in the
701 # shorter sequence
702 return _calculate_ratio(min(la, lb), la + lb)
704 def get_close_matches(word, possibilities, n=3, cutoff=0.6):
705 """Use SequenceMatcher to return list of the best "good enough" matches.
707 word is a sequence for which close matches are desired (typically a
708 string).
710 possibilities is a list of sequences against which to match word
711 (typically a list of strings).
713 Optional arg n (default 3) is the maximum number of close matches to
714 return. n must be > 0.
716 Optional arg cutoff (default 0.6) is a float in [0, 1]. Possibilities
717 that don't score at least that similar to word are ignored.
719 The best (no more than n) matches among the possibilities are returned
720 in a list, sorted by similarity score, most similar first.
722 >>> get_close_matches("appel", ["ape", "apple", "peach", "puppy"])
723 ['apple', 'ape']
724 >>> import keyword as _keyword
725 >>> get_close_matches("wheel", _keyword.kwlist)
726 ['while']
727 >>> get_close_matches("apple", _keyword.kwlist)
729 >>> get_close_matches("accept", _keyword.kwlist)
730 ['except']
733 if not n > 0:
734 raise ValueError("n must be > 0: %r" % (n,))
735 if not 0.0 <= cutoff <= 1.0:
736 raise ValueError("cutoff must be in [0.0, 1.0]: %r" % (cutoff,))
737 result = []
738 s = SequenceMatcher()
739 s.set_seq2(word)
740 for x in possibilities:
741 s.set_seq1(x)
742 if s.real_quick_ratio() >= cutoff and \
743 s.quick_ratio() >= cutoff and \
744 s.ratio() >= cutoff:
745 result.append((s.ratio(), x))
747 # Move the best scorers to head of list
748 result = heapq.nlargest(n, result)
749 # Strip scores for the best n matches
750 return [x for score, x in result]
752 def _count_leading(line, ch):
754 Return number of `ch` characters at the start of `line`.
756 Example:
758 >>> _count_leading(' abc', ' ')
762 i, n = 0, len(line)
763 while i < n and line[i] == ch:
764 i += 1
765 return i
767 class Differ:
768 r"""
769 Differ is a class for comparing sequences of lines of text, and
770 producing human-readable differences or deltas. Differ uses
771 SequenceMatcher both to compare sequences of lines, and to compare
772 sequences of characters within similar (near-matching) lines.
774 Each line of a Differ delta begins with a two-letter code:
776 '- ' line unique to sequence 1
777 '+ ' line unique to sequence 2
778 ' ' line common to both sequences
779 '? ' line not present in either input sequence
781 Lines beginning with '? ' attempt to guide the eye to intraline
782 differences, and were not present in either input sequence. These lines
783 can be confusing if the sequences contain tab characters.
785 Note that Differ makes no claim to produce a *minimal* diff. To the
786 contrary, minimal diffs are often counter-intuitive, because they synch
787 up anywhere possible, sometimes accidental matches 100 pages apart.
788 Restricting synch points to contiguous matches preserves some notion of
789 locality, at the occasional cost of producing a longer diff.
791 Example: Comparing two texts.
793 First we set up the texts, sequences of individual single-line strings
794 ending with newlines (such sequences can also be obtained from the
795 `readlines()` method of file-like objects):
797 >>> text1 = ''' 1. Beautiful is better than ugly.
798 ... 2. Explicit is better than implicit.
799 ... 3. Simple is better than complex.
800 ... 4. Complex is better than complicated.
801 ... '''.splitlines(1)
802 >>> len(text1)
804 >>> text1[0][-1]
805 '\n'
806 >>> text2 = ''' 1. Beautiful is better than ugly.
807 ... 3. Simple is better than complex.
808 ... 4. Complicated is better than complex.
809 ... 5. Flat is better than nested.
810 ... '''.splitlines(1)
812 Next we instantiate a Differ object:
814 >>> d = Differ()
816 Note that when instantiating a Differ object we may pass functions to
817 filter out line and character 'junk'. See Differ.__init__ for details.
819 Finally, we compare the two:
821 >>> result = list(d.compare(text1, text2))
823 'result' is a list of strings, so let's pretty-print it:
825 >>> from pprint import pprint as _pprint
826 >>> _pprint(result)
827 [' 1. Beautiful is better than ugly.\n',
828 '- 2. Explicit is better than implicit.\n',
829 '- 3. Simple is better than complex.\n',
830 '+ 3. Simple is better than complex.\n',
831 '? ++\n',
832 '- 4. Complex is better than complicated.\n',
833 '? ^ ---- ^\n',
834 '+ 4. Complicated is better than complex.\n',
835 '? ++++ ^ ^\n',
836 '+ 5. Flat is better than nested.\n']
838 As a single multi-line string it looks like this:
840 >>> print ''.join(result),
841 1. Beautiful is better than ugly.
842 - 2. Explicit is better than implicit.
843 - 3. Simple is better than complex.
844 + 3. Simple is better than complex.
845 ? ++
846 - 4. Complex is better than complicated.
847 ? ^ ---- ^
848 + 4. Complicated is better than complex.
849 ? ++++ ^ ^
850 + 5. Flat is better than nested.
852 Methods:
854 __init__(linejunk=None, charjunk=None)
855 Construct a text differencer, with optional filters.
857 compare(a, b)
858 Compare two sequences of lines; generate the resulting delta.
861 def __init__(self, linejunk=None, charjunk=None):
863 Construct a text differencer, with optional filters.
865 The two optional keyword parameters are for filter functions:
867 - `linejunk`: A function that should accept a single string argument,
868 and return true iff the string is junk. The module-level function
869 `IS_LINE_JUNK` may be used to filter out lines without visible
870 characters, except for at most one splat ('#'). It is recommended
871 to leave linejunk None; as of Python 2.3, the underlying
872 SequenceMatcher class has grown an adaptive notion of "noise" lines
873 that's better than any static definition the author has ever been
874 able to craft.
876 - `charjunk`: A function that should accept a string of length 1. The
877 module-level function `IS_CHARACTER_JUNK` may be used to filter out
878 whitespace characters (a blank or tab; **note**: bad idea to include
879 newline in this!). Use of IS_CHARACTER_JUNK is recommended.
882 self.linejunk = linejunk
883 self.charjunk = charjunk
885 def compare(self, a, b):
886 r"""
887 Compare two sequences of lines; generate the resulting delta.
889 Each sequence must contain individual single-line strings ending with
890 newlines. Such sequences can be obtained from the `readlines()` method
891 of file-like objects. The delta generated also consists of newline-
892 terminated strings, ready to be printed as-is via the writeline()
893 method of a file-like object.
895 Example:
897 >>> print ''.join(Differ().compare('one\ntwo\nthree\n'.splitlines(1),
898 ... 'ore\ntree\nemu\n'.splitlines(1))),
899 - one
901 + ore
903 - two
904 - three
906 + tree
907 + emu
910 cruncher = SequenceMatcher(self.linejunk, a, b)
911 for tag, alo, ahi, blo, bhi in cruncher.get_opcodes():
912 if tag == 'replace':
913 g = self._fancy_replace(a, alo, ahi, b, blo, bhi)
914 elif tag == 'delete':
915 g = self._dump('-', a, alo, ahi)
916 elif tag == 'insert':
917 g = self._dump('+', b, blo, bhi)
918 elif tag == 'equal':
919 g = self._dump(' ', a, alo, ahi)
920 else:
921 raise ValueError, 'unknown tag %r' % (tag,)
923 for line in g:
924 yield line
926 def _dump(self, tag, x, lo, hi):
927 """Generate comparison results for a same-tagged range."""
928 for i in xrange(lo, hi):
929 yield '%s %s' % (tag, x[i])
931 def _plain_replace(self, a, alo, ahi, b, blo, bhi):
932 assert alo < ahi and blo < bhi
933 # dump the shorter block first -- reduces the burden on short-term
934 # memory if the blocks are of very different sizes
935 if bhi - blo < ahi - alo:
936 first = self._dump('+', b, blo, bhi)
937 second = self._dump('-', a, alo, ahi)
938 else:
939 first = self._dump('-', a, alo, ahi)
940 second = self._dump('+', b, blo, bhi)
942 for g in first, second:
943 for line in g:
944 yield line
946 def _fancy_replace(self, a, alo, ahi, b, blo, bhi):
947 r"""
948 When replacing one block of lines with another, search the blocks
949 for *similar* lines; the best-matching pair (if any) is used as a
950 synch point, and intraline difference marking is done on the
951 similar pair. Lots of work, but often worth it.
953 Example:
955 >>> d = Differ()
956 >>> results = d._fancy_replace(['abcDefghiJkl\n'], 0, 1,
957 ... ['abcdefGhijkl\n'], 0, 1)
958 >>> print ''.join(results),
959 - abcDefghiJkl
960 ? ^ ^ ^
961 + abcdefGhijkl
962 ? ^ ^ ^
965 # don't synch up unless the lines have a similarity score of at
966 # least cutoff; best_ratio tracks the best score seen so far
967 best_ratio, cutoff = 0.74, 0.75
968 cruncher = SequenceMatcher(self.charjunk)
969 eqi, eqj = None, None # 1st indices of equal lines (if any)
971 # search for the pair that matches best without being identical
972 # (identical lines must be junk lines, & we don't want to synch up
973 # on junk -- unless we have to)
974 for j in xrange(blo, bhi):
975 bj = b[j]
976 cruncher.set_seq2(bj)
977 for i in xrange(alo, ahi):
978 ai = a[i]
979 if ai == bj:
980 if eqi is None:
981 eqi, eqj = i, j
982 continue
983 cruncher.set_seq1(ai)
984 # computing similarity is expensive, so use the quick
985 # upper bounds first -- have seen this speed up messy
986 # compares by a factor of 3.
987 # note that ratio() is only expensive to compute the first
988 # time it's called on a sequence pair; the expensive part
989 # of the computation is cached by cruncher
990 if cruncher.real_quick_ratio() > best_ratio and \
991 cruncher.quick_ratio() > best_ratio and \
992 cruncher.ratio() > best_ratio:
993 best_ratio, best_i, best_j = cruncher.ratio(), i, j
994 if best_ratio < cutoff:
995 # no non-identical "pretty close" pair
996 if eqi is None:
997 # no identical pair either -- treat it as a straight replace
998 for line in self._plain_replace(a, alo, ahi, b, blo, bhi):
999 yield line
1000 return
1001 # no close pair, but an identical pair -- synch up on that
1002 best_i, best_j, best_ratio = eqi, eqj, 1.0
1003 else:
1004 # there's a close pair, so forget the identical pair (if any)
1005 eqi = None
1007 # a[best_i] very similar to b[best_j]; eqi is None iff they're not
1008 # identical
1010 # pump out diffs from before the synch point
1011 for line in self._fancy_helper(a, alo, best_i, b, blo, best_j):
1012 yield line
1014 # do intraline marking on the synch pair
1015 aelt, belt = a[best_i], b[best_j]
1016 if eqi is None:
1017 # pump out a '-', '?', '+', '?' quad for the synched lines
1018 atags = btags = ""
1019 cruncher.set_seqs(aelt, belt)
1020 for tag, ai1, ai2, bj1, bj2 in cruncher.get_opcodes():
1021 la, lb = ai2 - ai1, bj2 - bj1
1022 if tag == 'replace':
1023 atags += '^' * la
1024 btags += '^' * lb
1025 elif tag == 'delete':
1026 atags += '-' * la
1027 elif tag == 'insert':
1028 btags += '+' * lb
1029 elif tag == 'equal':
1030 atags += ' ' * la
1031 btags += ' ' * lb
1032 else:
1033 raise ValueError, 'unknown tag %r' % (tag,)
1034 for line in self._qformat(aelt, belt, atags, btags):
1035 yield line
1036 else:
1037 # the synch pair is identical
1038 yield ' ' + aelt
1040 # pump out diffs from after the synch point
1041 for line in self._fancy_helper(a, best_i+1, ahi, b, best_j+1, bhi):
1042 yield line
1044 def _fancy_helper(self, a, alo, ahi, b, blo, bhi):
1045 g = []
1046 if alo < ahi:
1047 if blo < bhi:
1048 g = self._fancy_replace(a, alo, ahi, b, blo, bhi)
1049 else:
1050 g = self._dump('-', a, alo, ahi)
1051 elif blo < bhi:
1052 g = self._dump('+', b, blo, bhi)
1054 for line in g:
1055 yield line
1057 def _qformat(self, aline, bline, atags, btags):
1058 r"""
1059 Format "?" output and deal with leading tabs.
1061 Example:
1063 >>> d = Differ()
1064 >>> results = d._qformat('\tabcDefghiJkl\n', '\t\tabcdefGhijkl\n',
1065 ... ' ^ ^ ^ ', '+ ^ ^ ^ ')
1066 >>> for line in results: print repr(line)
1068 '- \tabcDefghiJkl\n'
1069 '? \t ^ ^ ^\n'
1070 '+ \t\tabcdefGhijkl\n'
1071 '? \t ^ ^ ^\n'
1074 # Can hurt, but will probably help most of the time.
1075 common = min(_count_leading(aline, "\t"),
1076 _count_leading(bline, "\t"))
1077 common = min(common, _count_leading(atags[:common], " "))
1078 atags = atags[common:].rstrip()
1079 btags = btags[common:].rstrip()
1081 yield "- " + aline
1082 if atags:
1083 yield "? %s%s\n" % ("\t" * common, atags)
1085 yield "+ " + bline
1086 if btags:
1087 yield "? %s%s\n" % ("\t" * common, btags)
1089 # With respect to junk, an earlier version of ndiff simply refused to
1090 # *start* a match with a junk element. The result was cases like this:
1091 # before: private Thread currentThread;
1092 # after: private volatile Thread currentThread;
1093 # If you consider whitespace to be junk, the longest contiguous match
1094 # not starting with junk is "e Thread currentThread". So ndiff reported
1095 # that "e volatil" was inserted between the 't' and the 'e' in "private".
1096 # While an accurate view, to people that's absurd. The current version
1097 # looks for matching blocks that are entirely junk-free, then extends the
1098 # longest one of those as far as possible but only with matching junk.
1099 # So now "currentThread" is matched, then extended to suck up the
1100 # preceding blank; then "private" is matched, and extended to suck up the
1101 # following blank; then "Thread" is matched; and finally ndiff reports
1102 # that "volatile " was inserted before "Thread". The only quibble
1103 # remaining is that perhaps it was really the case that " volatile"
1104 # was inserted after "private". I can live with that <wink>.
1106 import re
1108 def IS_LINE_JUNK(line, pat=re.compile(r"\s*#?\s*$").match):
1109 r"""
1110 Return 1 for ignorable line: iff `line` is blank or contains a single '#'.
1112 Examples:
1114 >>> IS_LINE_JUNK('\n')
1115 True
1116 >>> IS_LINE_JUNK(' # \n')
1117 True
1118 >>> IS_LINE_JUNK('hello\n')
1119 False
1122 return pat(line) is not None
1124 def IS_CHARACTER_JUNK(ch, ws=" \t"):
1125 r"""
1126 Return 1 for ignorable character: iff `ch` is a space or tab.
1128 Examples:
1130 >>> IS_CHARACTER_JUNK(' ')
1131 True
1132 >>> IS_CHARACTER_JUNK('\t')
1133 True
1134 >>> IS_CHARACTER_JUNK('\n')
1135 False
1136 >>> IS_CHARACTER_JUNK('x')
1137 False
1140 return ch in ws
1143 def unified_diff(a, b, fromfile='', tofile='', fromfiledate='',
1144 tofiledate='', n=3, lineterm='\n'):
1145 r"""
1146 Compare two sequences of lines; generate the delta as a unified diff.
1148 Unified diffs are a compact way of showing line changes and a few
1149 lines of context. The number of context lines is set by 'n' which
1150 defaults to three.
1152 By default, the diff control lines (those with ---, +++, or @@) are
1153 created with a trailing newline. This is helpful so that inputs
1154 created from file.readlines() result in diffs that are suitable for
1155 file.writelines() since both the inputs and outputs have trailing
1156 newlines.
1158 For inputs that do not have trailing newlines, set the lineterm
1159 argument to "" so that the output will be uniformly newline free.
1161 The unidiff format normally has a header for filenames and modification
1162 times. Any or all of these may be specified using strings for
1163 'fromfile', 'tofile', 'fromfiledate', and 'tofiledate'. The modification
1164 times are normally expressed in the format returned by time.ctime().
1166 Example:
1168 >>> for line in unified_diff('one two three four'.split(),
1169 ... 'zero one tree four'.split(), 'Original', 'Current',
1170 ... 'Sat Jan 26 23:30:50 1991', 'Fri Jun 06 10:20:52 2003',
1171 ... lineterm=''):
1172 ... print line
1173 --- Original Sat Jan 26 23:30:50 1991
1174 +++ Current Fri Jun 06 10:20:52 2003
1175 @@ -1,4 +1,4 @@
1176 +zero
1178 -two
1179 -three
1180 +tree
1181 four
1184 started = False
1185 for group in SequenceMatcher(None,a,b).get_grouped_opcodes(n):
1186 if not started:
1187 yield '--- %s %s%s' % (fromfile, fromfiledate, lineterm)
1188 yield '+++ %s %s%s' % (tofile, tofiledate, lineterm)
1189 started = True
1190 i1, i2, j1, j2 = group[0][1], group[-1][2], group[0][3], group[-1][4]
1191 yield "@@ -%d,%d +%d,%d @@%s" % (i1+1, i2-i1, j1+1, j2-j1, lineterm)
1192 for tag, i1, i2, j1, j2 in group:
1193 if tag == 'equal':
1194 for line in a[i1:i2]:
1195 yield ' ' + line
1196 continue
1197 if tag == 'replace' or tag == 'delete':
1198 for line in a[i1:i2]:
1199 yield '-' + line
1200 if tag == 'replace' or tag == 'insert':
1201 for line in b[j1:j2]:
1202 yield '+' + line
1204 # See http://www.unix.org/single_unix_specification/
1205 def context_diff(a, b, fromfile='', tofile='',
1206 fromfiledate='', tofiledate='', n=3, lineterm='\n'):
1207 r"""
1208 Compare two sequences of lines; generate the delta as a context diff.
1210 Context diffs are a compact way of showing line changes and a few
1211 lines of context. The number of context lines is set by 'n' which
1212 defaults to three.
1214 By default, the diff control lines (those with *** or ---) are
1215 created with a trailing newline. This is helpful so that inputs
1216 created from file.readlines() result in diffs that are suitable for
1217 file.writelines() since both the inputs and outputs have trailing
1218 newlines.
1220 For inputs that do not have trailing newlines, set the lineterm
1221 argument to "" so that the output will be uniformly newline free.
1223 The context diff format normally has a header for filenames and
1224 modification times. Any or all of these may be specified using
1225 strings for 'fromfile', 'tofile', 'fromfiledate', and 'tofiledate'.
1226 The modification times are normally expressed in the format returned
1227 by time.ctime(). If not specified, the strings default to blanks.
1229 Example:
1231 >>> print ''.join(context_diff('one\ntwo\nthree\nfour\n'.splitlines(1),
1232 ... 'zero\none\ntree\nfour\n'.splitlines(1), 'Original', 'Current',
1233 ... 'Sat Jan 26 23:30:50 1991', 'Fri Jun 06 10:22:46 2003')),
1234 *** Original Sat Jan 26 23:30:50 1991
1235 --- Current Fri Jun 06 10:22:46 2003
1236 ***************
1237 *** 1,4 ****
1239 ! two
1240 ! three
1241 four
1242 --- 1,4 ----
1243 + zero
1245 ! tree
1246 four
1249 started = False
1250 prefixmap = {'insert':'+ ', 'delete':'- ', 'replace':'! ', 'equal':' '}
1251 for group in SequenceMatcher(None,a,b).get_grouped_opcodes(n):
1252 if not started:
1253 yield '*** %s %s%s' % (fromfile, fromfiledate, lineterm)
1254 yield '--- %s %s%s' % (tofile, tofiledate, lineterm)
1255 started = True
1257 yield '***************%s' % (lineterm,)
1258 if group[-1][2] - group[0][1] >= 2:
1259 yield '*** %d,%d ****%s' % (group[0][1]+1, group[-1][2], lineterm)
1260 else:
1261 yield '*** %d ****%s' % (group[-1][2], lineterm)
1262 visiblechanges = [e for e in group if e[0] in ('replace', 'delete')]
1263 if visiblechanges:
1264 for tag, i1, i2, _, _ in group:
1265 if tag != 'insert':
1266 for line in a[i1:i2]:
1267 yield prefixmap[tag] + line
1269 if group[-1][4] - group[0][3] >= 2:
1270 yield '--- %d,%d ----%s' % (group[0][3]+1, group[-1][4], lineterm)
1271 else:
1272 yield '--- %d ----%s' % (group[-1][4], lineterm)
1273 visiblechanges = [e for e in group if e[0] in ('replace', 'insert')]
1274 if visiblechanges:
1275 for tag, _, _, j1, j2 in group:
1276 if tag != 'delete':
1277 for line in b[j1:j2]:
1278 yield prefixmap[tag] + line
1280 def ndiff(a, b, linejunk=None, charjunk=IS_CHARACTER_JUNK):
1281 r"""
1282 Compare `a` and `b` (lists of strings); return a `Differ`-style delta.
1284 Optional keyword parameters `linejunk` and `charjunk` are for filter
1285 functions (or None):
1287 - linejunk: A function that should accept a single string argument, and
1288 return true iff the string is junk. The default is None, and is
1289 recommended; as of Python 2.3, an adaptive notion of "noise" lines is
1290 used that does a good job on its own.
1292 - charjunk: A function that should accept a string of length 1. The
1293 default is module-level function IS_CHARACTER_JUNK, which filters out
1294 whitespace characters (a blank or tab; note: bad idea to include newline
1295 in this!).
1297 Tools/scripts/ndiff.py is a command-line front-end to this function.
1299 Example:
1301 >>> diff = ndiff('one\ntwo\nthree\n'.splitlines(1),
1302 ... 'ore\ntree\nemu\n'.splitlines(1))
1303 >>> print ''.join(diff),
1304 - one
1306 + ore
1308 - two
1309 - three
1311 + tree
1312 + emu
1314 return Differ(linejunk, charjunk).compare(a, b)
1316 def _mdiff(fromlines, tolines, context=None, linejunk=None,
1317 charjunk=IS_CHARACTER_JUNK):
1318 r"""Returns generator yielding marked up from/to side by side differences.
1320 Arguments:
1321 fromlines -- list of text lines to compared to tolines
1322 tolines -- list of text lines to be compared to fromlines
1323 context -- number of context lines to display on each side of difference,
1324 if None, all from/to text lines will be generated.
1325 linejunk -- passed on to ndiff (see ndiff documentation)
1326 charjunk -- passed on to ndiff (see ndiff documentation)
1328 This function returns an interator which returns a tuple:
1329 (from line tuple, to line tuple, boolean flag)
1331 from/to line tuple -- (line num, line text)
1332 line num -- integer or None (to indicate a context separation)
1333 line text -- original line text with following markers inserted:
1334 '\0+' -- marks start of added text
1335 '\0-' -- marks start of deleted text
1336 '\0^' -- marks start of changed text
1337 '\1' -- marks end of added/deleted/changed text
1339 boolean flag -- None indicates context separation, True indicates
1340 either "from" or "to" line contains a change, otherwise False.
1342 This function/iterator was originally developed to generate side by side
1343 file difference for making HTML pages (see HtmlDiff class for example
1344 usage).
1346 Note, this function utilizes the ndiff function to generate the side by
1347 side difference markup. Optional ndiff arguments may be passed to this
1348 function and they in turn will be passed to ndiff.
1350 import re
1352 # regular expression for finding intraline change indices
1353 change_re = re.compile('(\++|\-+|\^+)')
1355 # create the difference iterator to generate the differences
1356 diff_lines_iterator = ndiff(fromlines,tolines,linejunk,charjunk)
1358 def _make_line(lines, format_key, side, num_lines=[0,0]):
1359 """Returns line of text with user's change markup and line formatting.
1361 lines -- list of lines from the ndiff generator to produce a line of
1362 text from. When producing the line of text to return, the
1363 lines used are removed from this list.
1364 format_key -- '+' return first line in list with "add" markup around
1365 the entire line.
1366 '-' return first line in list with "delete" markup around
1367 the entire line.
1368 '?' return first line in list with add/delete/change
1369 intraline markup (indices obtained from second line)
1370 None return first line in list with no markup
1371 side -- indice into the num_lines list (0=from,1=to)
1372 num_lines -- from/to current line number. This is NOT intended to be a
1373 passed parameter. It is present as a keyword argument to
1374 maintain memory of the current line numbers between calls
1375 of this function.
1377 Note, this function is purposefully not defined at the module scope so
1378 that data it needs from its parent function (within whose context it
1379 is defined) does not need to be of module scope.
1381 num_lines[side] += 1
1382 # Handle case where no user markup is to be added, just return line of
1383 # text with user's line format to allow for usage of the line number.
1384 if format_key is None:
1385 return (num_lines[side],lines.pop(0)[2:])
1386 # Handle case of intraline changes
1387 if format_key == '?':
1388 text, markers = lines.pop(0), lines.pop(0)
1389 # find intraline changes (store change type and indices in tuples)
1390 sub_info = []
1391 def record_sub_info(match_object,sub_info=sub_info):
1392 sub_info.append([match_object.group(1)[0],match_object.span()])
1393 return match_object.group(1)
1394 change_re.sub(record_sub_info,markers)
1395 # process each tuple inserting our special marks that won't be
1396 # noticed by an xml/html escaper.
1397 for key,(begin,end) in sub_info[::-1]:
1398 text = text[0:begin]+'\0'+key+text[begin:end]+'\1'+text[end:]
1399 text = text[2:]
1400 # Handle case of add/delete entire line
1401 else:
1402 text = lines.pop(0)[2:]
1403 # if line of text is just a newline, insert a space so there is
1404 # something for the user to highlight and see.
1405 if not text:
1406 text = ' '
1407 # insert marks that won't be noticed by an xml/html escaper.
1408 text = '\0' + format_key + text + '\1'
1409 # Return line of text, first allow user's line formatter to do its
1410 # thing (such as adding the line number) then replace the special
1411 # marks with what the user's change markup.
1412 return (num_lines[side],text)
1414 def _line_iterator():
1415 """Yields from/to lines of text with a change indication.
1417 This function is an iterator. It itself pulls lines from a
1418 differencing iterator, processes them and yields them. When it can
1419 it yields both a "from" and a "to" line, otherwise it will yield one
1420 or the other. In addition to yielding the lines of from/to text, a
1421 boolean flag is yielded to indicate if the text line(s) have
1422 differences in them.
1424 Note, this function is purposefully not defined at the module scope so
1425 that data it needs from its parent function (within whose context it
1426 is defined) does not need to be of module scope.
1428 lines = []
1429 num_blanks_pending, num_blanks_to_yield = 0, 0
1430 while True:
1431 # Load up next 4 lines so we can look ahead, create strings which
1432 # are a concatenation of the first character of each of the 4 lines
1433 # so we can do some very readable comparisons.
1434 while len(lines) < 4:
1435 try:
1436 lines.append(diff_lines_iterator.next())
1437 except StopIteration:
1438 lines.append('X')
1439 s = ''.join([line[0] for line in lines])
1440 if s.startswith('X'):
1441 # When no more lines, pump out any remaining blank lines so the
1442 # corresponding add/delete lines get a matching blank line so
1443 # all line pairs get yielded at the next level.
1444 num_blanks_to_yield = num_blanks_pending
1445 elif s.startswith('-?+?'):
1446 # simple intraline change
1447 yield _make_line(lines,'?',0), _make_line(lines,'?',1), True
1448 continue
1449 elif s.startswith('--++'):
1450 # in delete block, add block coming: we do NOT want to get
1451 # caught up on blank lines yet, just process the delete line
1452 num_blanks_pending -= 1
1453 yield _make_line(lines,'-',0), None, True
1454 continue
1455 elif s.startswith(('--?+', '--+', '- ')):
1456 # in delete block and see a intraline change or unchanged line
1457 # coming: yield the delete line and then blanks
1458 from_line,to_line = _make_line(lines,'-',0), None
1459 num_blanks_to_yield,num_blanks_pending = num_blanks_pending-1,0
1460 elif s.startswith('-+?'):
1461 # intraline change
1462 yield _make_line(lines,None,0), _make_line(lines,'?',1), True
1463 continue
1464 elif s.startswith('-?+'):
1465 # intraline change
1466 yield _make_line(lines,'?',0), _make_line(lines,None,1), True
1467 continue
1468 elif s.startswith('-'):
1469 # delete FROM line
1470 num_blanks_pending -= 1
1471 yield _make_line(lines,'-',0), None, True
1472 continue
1473 elif s.startswith('+--'):
1474 # in add block, delete block coming: we do NOT want to get
1475 # caught up on blank lines yet, just process the add line
1476 num_blanks_pending += 1
1477 yield None, _make_line(lines,'+',1), True
1478 continue
1479 elif s.startswith(('+ ', '+-')):
1480 # will be leaving an add block: yield blanks then add line
1481 from_line, to_line = None, _make_line(lines,'+',1)
1482 num_blanks_to_yield,num_blanks_pending = num_blanks_pending+1,0
1483 elif s.startswith('+'):
1484 # inside an add block, yield the add line
1485 num_blanks_pending += 1
1486 yield None, _make_line(lines,'+',1), True
1487 continue
1488 elif s.startswith(' '):
1489 # unchanged text, yield it to both sides
1490 yield _make_line(lines[:],None,0),_make_line(lines,None,1),False
1491 continue
1492 # Catch up on the blank lines so when we yield the next from/to
1493 # pair, they are lined up.
1494 while(num_blanks_to_yield < 0):
1495 num_blanks_to_yield += 1
1496 yield None,('','\n'),True
1497 while(num_blanks_to_yield > 0):
1498 num_blanks_to_yield -= 1
1499 yield ('','\n'),None,True
1500 if s.startswith('X'):
1501 raise StopIteration
1502 else:
1503 yield from_line,to_line,True
1505 def _line_pair_iterator():
1506 """Yields from/to lines of text with a change indication.
1508 This function is an iterator. It itself pulls lines from the line
1509 iterator. Its difference from that iterator is that this function
1510 always yields a pair of from/to text lines (with the change
1511 indication). If necessary it will collect single from/to lines
1512 until it has a matching pair from/to pair to yield.
1514 Note, this function is purposefully not defined at the module scope so
1515 that data it needs from its parent function (within whose context it
1516 is defined) does not need to be of module scope.
1518 line_iterator = _line_iterator()
1519 fromlines,tolines=[],[]
1520 while True:
1521 # Collecting lines of text until we have a from/to pair
1522 while (len(fromlines)==0 or len(tolines)==0):
1523 from_line, to_line, found_diff =line_iterator.next()
1524 if from_line is not None:
1525 fromlines.append((from_line,found_diff))
1526 if to_line is not None:
1527 tolines.append((to_line,found_diff))
1528 # Once we have a pair, remove them from the collection and yield it
1529 from_line, fromDiff = fromlines.pop(0)
1530 to_line, to_diff = tolines.pop(0)
1531 yield (from_line,to_line,fromDiff or to_diff)
1533 # Handle case where user does not want context differencing, just yield
1534 # them up without doing anything else with them.
1535 line_pair_iterator = _line_pair_iterator()
1536 if context is None:
1537 while True:
1538 yield line_pair_iterator.next()
1539 # Handle case where user wants context differencing. We must do some
1540 # storage of lines until we know for sure that they are to be yielded.
1541 else:
1542 context += 1
1543 lines_to_write = 0
1544 while True:
1545 # Store lines up until we find a difference, note use of a
1546 # circular queue because we only need to keep around what
1547 # we need for context.
1548 index, contextLines = 0, [None]*(context)
1549 found_diff = False
1550 while(found_diff is False):
1551 from_line, to_line, found_diff = line_pair_iterator.next()
1552 i = index % context
1553 contextLines[i] = (from_line, to_line, found_diff)
1554 index += 1
1555 # Yield lines that we have collected so far, but first yield
1556 # the user's separator.
1557 if index > context:
1558 yield None, None, None
1559 lines_to_write = context
1560 else:
1561 lines_to_write = index
1562 index = 0
1563 while(lines_to_write):
1564 i = index % context
1565 index += 1
1566 yield contextLines[i]
1567 lines_to_write -= 1
1568 # Now yield the context lines after the change
1569 lines_to_write = context-1
1570 while(lines_to_write):
1571 from_line, to_line, found_diff = line_pair_iterator.next()
1572 # If another change within the context, extend the context
1573 if found_diff:
1574 lines_to_write = context-1
1575 else:
1576 lines_to_write -= 1
1577 yield from_line, to_line, found_diff
1580 _file_template = """
1581 <!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Transitional//EN"
1582 "http://www.w3.org/TR/xhtml1/DTD/xhtml1-transitional.dtd">
1584 <html>
1586 <head>
1587 <meta http-equiv="Content-Type"
1588 content="text/html; charset=ISO-8859-1" />
1589 <title></title>
1590 <style type="text/css">%(styles)s
1591 </style>
1592 </head>
1594 <body>
1595 %(table)s%(legend)s
1596 </body>
1598 </html>"""
1600 _styles = """
1601 table.diff {font-family:Courier; border:medium;}
1602 .diff_header {background-color:#e0e0e0}
1603 td.diff_header {text-align:right}
1604 .diff_next {background-color:#c0c0c0}
1605 .diff_add {background-color:#aaffaa}
1606 .diff_chg {background-color:#ffff77}
1607 .diff_sub {background-color:#ffaaaa}"""
1609 _table_template = """
1610 <table class="diff" id="difflib_chg_%(prefix)s_top"
1611 cellspacing="0" cellpadding="0" rules="groups" >
1612 <colgroup></colgroup> <colgroup></colgroup> <colgroup></colgroup>
1613 <colgroup></colgroup> <colgroup></colgroup> <colgroup></colgroup>
1614 %(header_row)s
1615 <tbody>
1616 %(data_rows)s </tbody>
1617 </table>"""
1619 _legend = """
1620 <table class="diff" summary="Legends">
1621 <tr> <th colspan="2"> Legends </th> </tr>
1622 <tr> <td> <table border="" summary="Colors">
1623 <tr><th> Colors </th> </tr>
1624 <tr><td class="diff_add">&nbsp;Added&nbsp;</td></tr>
1625 <tr><td class="diff_chg">Changed</td> </tr>
1626 <tr><td class="diff_sub">Deleted</td> </tr>
1627 </table></td>
1628 <td> <table border="" summary="Links">
1629 <tr><th colspan="2"> Links </th> </tr>
1630 <tr><td>(f)irst change</td> </tr>
1631 <tr><td>(n)ext change</td> </tr>
1632 <tr><td>(t)op</td> </tr>
1633 </table></td> </tr>
1634 </table>"""
1636 class HtmlDiff(object):
1637 """For producing HTML side by side comparison with change highlights.
1639 This class can be used to create an HTML table (or a complete HTML file
1640 containing the table) showing a side by side, line by line comparison
1641 of text with inter-line and intra-line change highlights. The table can
1642 be generated in either full or contextual difference mode.
1644 The following methods are provided for HTML generation:
1646 make_table -- generates HTML for a single side by side table
1647 make_file -- generates complete HTML file with a single side by side table
1649 See tools/scripts/diff.py for an example usage of this class.
1652 _file_template = _file_template
1653 _styles = _styles
1654 _table_template = _table_template
1655 _legend = _legend
1656 _default_prefix = 0
1658 def __init__(self,tabsize=8,wrapcolumn=None,linejunk=None,
1659 charjunk=IS_CHARACTER_JUNK):
1660 """HtmlDiff instance initializer
1662 Arguments:
1663 tabsize -- tab stop spacing, defaults to 8.
1664 wrapcolumn -- column number where lines are broken and wrapped,
1665 defaults to None where lines are not wrapped.
1666 linejunk,charjunk -- keyword arguments passed into ndiff() (used to by
1667 HtmlDiff() to generate the side by side HTML differences). See
1668 ndiff() documentation for argument default values and descriptions.
1670 self._tabsize = tabsize
1671 self._wrapcolumn = wrapcolumn
1672 self._linejunk = linejunk
1673 self._charjunk = charjunk
1675 def make_file(self,fromlines,tolines,fromdesc='',todesc='',context=False,
1676 numlines=5):
1677 """Returns HTML file of side by side comparison with change highlights
1679 Arguments:
1680 fromlines -- list of "from" lines
1681 tolines -- list of "to" lines
1682 fromdesc -- "from" file column header string
1683 todesc -- "to" file column header string
1684 context -- set to True for contextual differences (defaults to False
1685 which shows full differences).
1686 numlines -- number of context lines. When context is set True,
1687 controls number of lines displayed before and after the change.
1688 When context is False, controls the number of lines to place
1689 the "next" link anchors before the next change (so click of
1690 "next" link jumps to just before the change).
1693 return self._file_template % dict(
1694 styles = self._styles,
1695 legend = self._legend,
1696 table = self.make_table(fromlines,tolines,fromdesc,todesc,
1697 context=context,numlines=numlines))
1699 def _tab_newline_replace(self,fromlines,tolines):
1700 """Returns from/to line lists with tabs expanded and newlines removed.
1702 Instead of tab characters being replaced by the number of spaces
1703 needed to fill in to the next tab stop, this function will fill
1704 the space with tab characters. This is done so that the difference
1705 algorithms can identify changes in a file when tabs are replaced by
1706 spaces and vice versa. At the end of the HTML generation, the tab
1707 characters will be replaced with a nonbreakable space.
1709 def expand_tabs(line):
1710 # hide real spaces
1711 line = line.replace(' ','\0')
1712 # expand tabs into spaces
1713 line = line.expandtabs(self._tabsize)
1714 # relace spaces from expanded tabs back into tab characters
1715 # (we'll replace them with markup after we do differencing)
1716 line = line.replace(' ','\t')
1717 return line.replace('\0',' ').rstrip('\n')
1718 fromlines = [expand_tabs(line) for line in fromlines]
1719 tolines = [expand_tabs(line) for line in tolines]
1720 return fromlines,tolines
1722 def _split_line(self,data_list,line_num,text):
1723 """Builds list of text lines by splitting text lines at wrap point
1725 This function will determine if the input text line needs to be
1726 wrapped (split) into separate lines. If so, the first wrap point
1727 will be determined and the first line appended to the output
1728 text line list. This function is used recursively to handle
1729 the second part of the split line to further split it.
1731 # if blank line or context separator, just add it to the output list
1732 if not line_num:
1733 data_list.append((line_num,text))
1734 return
1736 # if line text doesn't need wrapping, just add it to the output list
1737 size = len(text)
1738 max = self._wrapcolumn
1739 if (size <= max) or ((size -(text.count('\0')*3)) <= max):
1740 data_list.append((line_num,text))
1741 return
1743 # scan text looking for the wrap point, keeping track if the wrap
1744 # point is inside markers
1745 i = 0
1746 n = 0
1747 mark = ''
1748 while n < max and i < size:
1749 if text[i] == '\0':
1750 i += 1
1751 mark = text[i]
1752 i += 1
1753 elif text[i] == '\1':
1754 i += 1
1755 mark = ''
1756 else:
1757 i += 1
1758 n += 1
1760 # wrap point is inside text, break it up into separate lines
1761 line1 = text[:i]
1762 line2 = text[i:]
1764 # if wrap point is inside markers, place end marker at end of first
1765 # line and start marker at beginning of second line because each
1766 # line will have its own table tag markup around it.
1767 if mark:
1768 line1 = line1 + '\1'
1769 line2 = '\0' + mark + line2
1771 # tack on first line onto the output list
1772 data_list.append((line_num,line1))
1774 # use this routine again to wrap the remaining text
1775 self._split_line(data_list,'>',line2)
1777 def _line_wrapper(self,diffs):
1778 """Returns iterator that splits (wraps) mdiff text lines"""
1780 # pull from/to data and flags from mdiff iterator
1781 for fromdata,todata,flag in diffs:
1782 # check for context separators and pass them through
1783 if flag is None:
1784 yield fromdata,todata,flag
1785 continue
1786 (fromline,fromtext),(toline,totext) = fromdata,todata
1787 # for each from/to line split it at the wrap column to form
1788 # list of text lines.
1789 fromlist,tolist = [],[]
1790 self._split_line(fromlist,fromline,fromtext)
1791 self._split_line(tolist,toline,totext)
1792 # yield from/to line in pairs inserting blank lines as
1793 # necessary when one side has more wrapped lines
1794 while fromlist or tolist:
1795 if fromlist:
1796 fromdata = fromlist.pop(0)
1797 else:
1798 fromdata = ('',' ')
1799 if tolist:
1800 todata = tolist.pop(0)
1801 else:
1802 todata = ('',' ')
1803 yield fromdata,todata,flag
1805 def _collect_lines(self,diffs):
1806 """Collects mdiff output into separate lists
1808 Before storing the mdiff from/to data into a list, it is converted
1809 into a single line of text with HTML markup.
1812 fromlist,tolist,flaglist = [],[],[]
1813 # pull from/to data and flags from mdiff style iterator
1814 for fromdata,todata,flag in diffs:
1815 try:
1816 # store HTML markup of the lines into the lists
1817 fromlist.append(self._format_line(0,flag,*fromdata))
1818 tolist.append(self._format_line(1,flag,*todata))
1819 except TypeError:
1820 # exceptions occur for lines where context separators go
1821 fromlist.append(None)
1822 tolist.append(None)
1823 flaglist.append(flag)
1824 return fromlist,tolist,flaglist
1826 def _format_line(self,side,flag,linenum,text):
1827 """Returns HTML markup of "from" / "to" text lines
1829 side -- 0 or 1 indicating "from" or "to" text
1830 flag -- indicates if difference on line
1831 linenum -- line number (used for line number column)
1832 text -- line text to be marked up
1834 try:
1835 linenum = '%d' % linenum
1836 id = ' id="%s%s"' % (self._prefix[side],linenum)
1837 except TypeError:
1838 # handle blank lines where linenum is '>' or ''
1839 id = ''
1840 # replace those things that would get confused with HTML symbols
1841 text=text.replace("&","&amp;").replace(">","&gt;").replace("<","&lt;")
1843 # make space non-breakable so they don't get compressed or line wrapped
1844 text = text.replace(' ','&nbsp;').rstrip()
1846 return '<td class="diff_header"%s>%s</td><td nowrap="nowrap">%s</td>' \
1847 % (id,linenum,text)
1849 def _make_prefix(self):
1850 """Create unique anchor prefixes"""
1852 # Generate a unique anchor prefix so multiple tables
1853 # can exist on the same HTML page without conflicts.
1854 fromprefix = "from%d_" % HtmlDiff._default_prefix
1855 toprefix = "to%d_" % HtmlDiff._default_prefix
1856 HtmlDiff._default_prefix += 1
1857 # store prefixes so line format method has access
1858 self._prefix = [fromprefix,toprefix]
1860 def _convert_flags(self,fromlist,tolist,flaglist,context,numlines):
1861 """Makes list of "next" links"""
1863 # all anchor names will be generated using the unique "to" prefix
1864 toprefix = self._prefix[1]
1866 # process change flags, generating middle column of next anchors/links
1867 next_id = ['']*len(flaglist)
1868 next_href = ['']*len(flaglist)
1869 num_chg, in_change = 0, False
1870 last = 0
1871 for i,flag in enumerate(flaglist):
1872 if flag:
1873 if not in_change:
1874 in_change = True
1875 last = i
1876 # at the beginning of a change, drop an anchor a few lines
1877 # (the context lines) before the change for the previous
1878 # link
1879 i = max([0,i-numlines])
1880 next_id[i] = ' id="difflib_chg_%s_%d"' % (toprefix,num_chg)
1881 # at the beginning of a change, drop a link to the next
1882 # change
1883 num_chg += 1
1884 next_href[last] = '<a href="#difflib_chg_%s_%d">n</a>' % (
1885 toprefix,num_chg)
1886 else:
1887 in_change = False
1888 # check for cases where there is no content to avoid exceptions
1889 if not flaglist:
1890 flaglist = [False]
1891 next_id = ['']
1892 next_href = ['']
1893 last = 0
1894 if context:
1895 fromlist = ['<td></td><td>&nbsp;No Differences Found&nbsp;</td>']
1896 tolist = fromlist
1897 else:
1898 fromlist = tolist = ['<td></td><td>&nbsp;Empty File&nbsp;</td>']
1899 # if not a change on first line, drop a link
1900 if not flaglist[0]:
1901 next_href[0] = '<a href="#difflib_chg_%s_0">f</a>' % toprefix
1902 # redo the last link to link to the top
1903 next_href[last] = '<a href="#difflib_chg_%s_top">t</a>' % (toprefix)
1905 return fromlist,tolist,flaglist,next_href,next_id
1907 def make_table(self,fromlines,tolines,fromdesc='',todesc='',context=False,
1908 numlines=5):
1909 """Returns HTML table of side by side comparison with change highlights
1911 Arguments:
1912 fromlines -- list of "from" lines
1913 tolines -- list of "to" lines
1914 fromdesc -- "from" file column header string
1915 todesc -- "to" file column header string
1916 context -- set to True for contextual differences (defaults to False
1917 which shows full differences).
1918 numlines -- number of context lines. When context is set True,
1919 controls number of lines displayed before and after the change.
1920 When context is False, controls the number of lines to place
1921 the "next" link anchors before the next change (so click of
1922 "next" link jumps to just before the change).
1925 # make unique anchor prefixes so that multiple tables may exist
1926 # on the same page without conflict.
1927 self._make_prefix()
1929 # change tabs to spaces before it gets more difficult after we insert
1930 # markkup
1931 fromlines,tolines = self._tab_newline_replace(fromlines,tolines)
1933 # create diffs iterator which generates side by side from/to data
1934 if context:
1935 context_lines = numlines
1936 else:
1937 context_lines = None
1938 diffs = _mdiff(fromlines,tolines,context_lines,linejunk=self._linejunk,
1939 charjunk=self._charjunk)
1941 # set up iterator to wrap lines that exceed desired width
1942 if self._wrapcolumn:
1943 diffs = self._line_wrapper(diffs)
1945 # collect up from/to lines and flags into lists (also format the lines)
1946 fromlist,tolist,flaglist = self._collect_lines(diffs)
1948 # process change flags, generating middle column of next anchors/links
1949 fromlist,tolist,flaglist,next_href,next_id = self._convert_flags(
1950 fromlist,tolist,flaglist,context,numlines)
1952 s = []
1953 fmt = ' <tr><td class="diff_next"%s>%s</td>%s' + \
1954 '<td class="diff_next">%s</td>%s</tr>\n'
1955 for i in range(len(flaglist)):
1956 if flaglist[i] is None:
1957 # mdiff yields None on separator lines skip the bogus ones
1958 # generated for the first line
1959 if i > 0:
1960 s.append(' </tbody> \n <tbody>\n')
1961 else:
1962 s.append( fmt % (next_id[i],next_href[i],fromlist[i],
1963 next_href[i],tolist[i]))
1964 if fromdesc or todesc:
1965 header_row = '<thead><tr>%s%s%s%s</tr></thead>' % (
1966 '<th class="diff_next"><br /></th>',
1967 '<th colspan="2" class="diff_header">%s</th>' % fromdesc,
1968 '<th class="diff_next"><br /></th>',
1969 '<th colspan="2" class="diff_header">%s</th>' % todesc)
1970 else:
1971 header_row = ''
1973 table = self._table_template % dict(
1974 data_rows=''.join(s),
1975 header_row=header_row,
1976 prefix=self._prefix[1])
1978 return table.replace('\0+','<span class="diff_add">'). \
1979 replace('\0-','<span class="diff_sub">'). \
1980 replace('\0^','<span class="diff_chg">'). \
1981 replace('\1','</span>'). \
1982 replace('\t','&nbsp;')
1984 del re
1986 def restore(delta, which):
1987 r"""
1988 Generate one of the two sequences that generated a delta.
1990 Given a `delta` produced by `Differ.compare()` or `ndiff()`, extract
1991 lines originating from file 1 or 2 (parameter `which`), stripping off line
1992 prefixes.
1994 Examples:
1996 >>> diff = ndiff('one\ntwo\nthree\n'.splitlines(1),
1997 ... 'ore\ntree\nemu\n'.splitlines(1))
1998 >>> diff = list(diff)
1999 >>> print ''.join(restore(diff, 1)),
2002 three
2003 >>> print ''.join(restore(diff, 2)),
2005 tree
2008 try:
2009 tag = {1: "- ", 2: "+ "}[int(which)]
2010 except KeyError:
2011 raise ValueError, ('unknown delta choice (must be 1 or 2): %r'
2012 % which)
2013 prefixes = (" ", tag)
2014 for line in delta:
2015 if line[:2] in prefixes:
2016 yield line[2:]
2018 def _test():
2019 import doctest, difflib
2020 return doctest.testmod(difflib)
2022 if __name__ == "__main__":
2023 _test()